KR100360377B1 - Steel structure with damper joint - Google Patents

Abstract

The present invention provides a damper connecting the joints of the "H" shaped beams to a column having a closed section such as a square steel pipe in a building structure by using a damper, thereby improving the structural performance of the joint, and easy to repair and reinforce even after an earthquake. Its purpose is to provide a steel frame structure having a.

The steel structure having the damper joint of the present invention is to connect the pillar and the beam to each other in the steel structure, and when the beam is attached to the pillar, only the web of the beam is fixed to the pillar, and the load applied to the beam can be attenuated. And a damper 10. In the steel structure having the damper joint of the present invention, the adapter plate 11 of the damper 10 is fixed to both corners of the column so as to be parallel to the beam axis and perpendicular to the flange of the beam, and the damper 10 The slit plate 12 formed of the plurality of struts 13 is fixed to both sides of the adapter plate 11 and the flange, so that even if a load is applied to the beam, only the struts 13 are broken, thereby Structurally stabilize the columns and beams.

Description

Steel structure with damper joint

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to steel structures having damper joints, and in particular, pin connections and semi-rigid connections used when joining steel pipe columns and "H" beams. The present invention relates to a steel structure having a damper joint used for a building structure composed of a joint and a rigid connection.

In general, in a structure having a steel structure, square steel pipes and hollow steel pipes are used as columns. This steel pipe column has a closed cross section, and is welded or bolted to form a steel structure. The steel pipe column and the "H" steel beam of this steel structure is bonded with concrete after joining after construction.

Since the cross section of the column is a closed section at the junction of the steel pipe column and the "H" shaped beam, a method for connecting the "H" shaped beam to the pillar is important.

Steel structure according to the prior art, as shown in Figure 1, is composed of a steel pipe column (1) erected in a vertical direction and "H" shaped beams (2) bonded in a horizontal direction. Here, the "H" shaped beams 2 are formed of webs 3 fixed vertically at the center of the flanges 4 formed at the top and the bottom. And the diaphragm 5 (diaphragm) is provided in the junction part of the steel pipe column 1 and the "H" shaped beams 2. The diaphragm 5 is a joining member for firmly joining the steel pipe pillar 1 and the "H" shaped beams 2, and is formed to enclose the circumference of the steel pipe pillar 1 as a band having a plurality of angles, or a steel pipe pillar. (1) It is a joining member formed integrally so that it may cut | disconnect and arrange between the cut | disconnected parts.

In the conventional steel structure, the steel pipe column 1 and the "H" -shaped steel beam 2 are welded to each other in the diaphragm 5 to design a joint close to the steel joint.

Since the joint part of the conventional steel structure is complicated in the manufacturing process and the diaphragm 5 is installed by cutting the steel pipe column 1 for each floor of the building to which the "H" shaped beams 2 are joined, the joint part must be welded. In many cases, the economy is disadvantageous.

In addition, since the joint is strongly designed at the joint of a conventional steel structure, when the lateral load such as earthquake load and wind load are applied, the main member that forms a frame such as a column or beam is applied. It has the disadvantage of surrendering. In addition, as the main member enters the plastic zone, there is a disadvantage in that the behavior of the steel structure becomes unstable due to buckling and deterioration of the strength of the main member.

In addition, the joint portion of the conventional steel structure is deformed before the column and beam when the lateral load as described above acts, it is often disadvantageous for the lateral displacement control of the entire building.

In addition, when the joint portion of the conventional steel structure using bolt coupling, by forming a bolt coupling hole in the pillar, there is a disadvantage in having a complicated manufacturing process. In addition, when the column is filled with concrete, the joining portion of the steel structure using the bolt coupling may have a poor charging performance for the bolts passing through the column, and when the bolt is surrendered, the bolt attached to the concrete in the column It is difficult to replace.

In addition, in the case of earthquake-resistant design considering the occurrence of earthquake in the joint of steel structure, when the earthquake occurs while the main structural members such as columns and beams support the vertical load by the weight of the building, Therefore, the design of the main structural member is very complicated, and there are many difficulties in controlling the yield mechanism of the structure.

The present invention has been made in order to solve the problems of the prior art as described above, by connecting the joints "H" shaped beams are bonded to the column having a closed section such as a square steel pipe in the building structure with a damper, the structural performance of the joint It is an object of the present invention to provide a steel structure having a damper joint which is easy to repair and reinforce even after an earthquake occurs.

1 is a perspective view for explaining the configuration of a steel structure having a steel joint according to the prior art.

Figure 2 is a front view for explaining the structure of the steel structure having a damper joint according to an embodiment of the present invention.

3 is a cross-sectional view for explaining the coupling relationship of the steel structure having a damper joint shown in FIG.

4 is a graph for explaining the experimental results of the steel structure having a damper joint shown in FIG.

5 is a perspective view for explaining the situation after the end of the experiment of the steel structure having a damper joint shown in FIG.

♠ Explanation of symbols on the main parts of the drawing ♠

1: pillar 2: beam

3: web 4: flange

10 damper 11 adapter plate

12: slit plate 13: strut

According to the present invention for achieving the object as described above, there is provided a steel structure having a damper joint connecting the columns and beams in the steel structure. The steel structure provided with such a damper joint of the present invention, when the beam is attached to a pillar, includes only the web of the beam to the pillar, and includes a damper capable of damping the load applied to the beam. In addition, the steel structure having a damper joint of the present invention is the adapter plate of the damper is fixed to both corners of the column so that the adapter plate of the damper is parallel to the axial direction of the beam and perpendicular to the flange of the beam, a slit formed of a plurality of struts of the damper The plate is fixed to both sides of the adapter plate and the flange so that even when a load is applied to the beam, only the struts are broken, thereby structurally stabilizing the pillar and the beam.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of a steel structure having a damper joint according to the present invention will be described in detail.

2 is a front view illustrating a structure of a steel structure having a damper joint according to an embodiment of the present invention, and FIG. 3 illustrates a coupling relationship of the steel structure having a damper joint shown in FIG. 2. 4 is a graph illustrating the experimental results of the steel structure having the damper joint shown in FIG. 2, and FIG. 5 is a situation after the end of the experiment of the steel structure having the damper joint shown in FIG. 2. A perspective view for explaining.

As shown in Figures 2 to 4, the steel frame structure of the present invention was used by attaching a damper 10 to the junction of the steel pipe column (1) and the "H" shaped beams (2). Here, the "H" shaped beams 2 used cut the flanges 4 at the axial ends to a predetermined size. Therefore, the axial end of the "H" shaped steel beam 2 is fixed by welding or bolting only at the end of the web 3 at the center of the side of the steel pipe column 1. The damper 10 is fixed in the axial direction of the "H" -shaped steel beam 2 at the corner of such a steel pipe column 1.

Such damper 10 has an adapter plate 11 welded at right angles to flange 4. Between such a center position in the vertical direction of the adapter plate 11 and the flange 4, the damping action is actually slit plate 12 (slit-plate) at the axial end of the flange 4 in parallel with the flange (4) Welded in the direction.

In the slit plate 12 of the damper 10 fixed as described above, struts 13 are formed to have the shape of the holes of the brick block so that the struts 13 resist external forces. The size of this slit plate 12 should be properly determined according to the design load of the joint of the steel structure, it is better not to be thicker than the thickness of the flange (4).

Since the steel frame structure having the damper joint of the present invention uses the damper 10 as described above for the joint, the damper 10 has a relatively large lateral stiffness and sufficient plastic deformation capacity, so that the damper 10 Due to the deformation of the slit plate 12, most of the input energy due to the action of the lateral force such as an earthquake can be absorbed.

In addition, even when the damper 10 has undergone sufficient plastic deformation, the main members such as the steel pipe column 1 and the "H" shaped steel beam 2 remain elastic. Therefore, even when the action of the lateral force such as the earthquake ends, the member entering the plastic zone is limited to the damper 10.

Therefore, the steel frame structure provided with the damper joining part of this invention can make a healthy steel frame structure before an earthquake even if only damper 10 is replaced, even in the above-mentioned situation.

4 shows the load-displacement curve of the steel structure provided with the damper joint of the present invention and the lateral load of the joint. As can be seen in Figure 4, the hysteretic behavior of the junction shows a very stable form, it can be seen that it has a sufficient plastic deformation capacity.

In FIG. 5, after completion of the experiment as described above, the final state of the joint portion of the steel structure having a damper joint portion of the present invention is shown.

Here, although the joints of the steel structure are cut by the lateral load applied in the transverse direction (a), the struts 13 of the slit plate 12 are cut at the damper 10, but the steel pipe column 1 and the "H" shaped beam ( It can be seen that 2) is almost elastically connected. Therefore, it can be seen that the structural performance of the joint portion of the bone structure mainly depends on the performance of the strut 13.

Therefore, the designer who designs the building using the steel structure only needs to consider the strut 13 performance in the steel structure having the damper joint of the present invention, thereby designing the joint portion of the steel pipe column 1 and the "H" shaped steel beam 2. It can be very simple.

As described in detail above, in the steel frame structure having the damper joint of the present invention, a main structural member such as a column or beam is designed to bear only a vertical load such as the weight of a building and a lateral load such as wind and earthquake as a damper of the joint. There is a possible advantage.

In addition, the steel structure having the damper joint of the present invention can be economically designed to reduce the cross-section because the main structural member only needs to consider the vertical load, and because the hysteretic characteristics of the damper of the joint is stable, the earthquake of the whole structure The response characteristics are improved and stable hysteresis behavior can be obtained.

In the above description, the technical idea of the steel structure having the damper joint of the present invention has been described together with the accompanying drawings, but this is by way of example only and not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (1)

In connecting the columns and beams to each other in the steel structure, When attaching a beam to a column, only the web of the beam is fixed to the column, A damper (10) capable of damping the load applied to the beam, The adapter plate 11 of the damper 10 is fixed to both corners of the column so as to be parallel to the beam axial direction and perpendicular to the flange of the beam, The slit plate 12 formed of the plurality of struts 13 of the damper 10 is fixed to both sides of the adapter plate 11 and the flange, so that even if a load is applied to the beam, only the struts 13 The steel frame structure provided with the damper joint part characterized by structurally stabilizing the said pillar and the beam by this damage.